动态检测活细胞内泛素-蛋白酶体系统活性方法的建立

目的建立一种动态检测活细胞内泛素-蛋白酶体系统活性的方法。方法将表达绿色荧光蛋白（GFP）或红色荧光蛋白（DsRed2）的质粒分别改建为表达带有内泛素-蛋白酶体系统降解信号CL1的GFP或DsRed2的pGFP^u或pDsRed2质粒,然后转染HEK293细胞,通过G418筛选得到稳定表达GFP^u或DsRed2^u的细胞系。在蛋白酶体抑制N—Acetyl—Leu-Leu—Norleu—al（ALLN）处理GFP^u或DsRed2^u细胞后,应用免疫印记技术检测细胞内GFP或DsRed,含量的变化,应用荧光显微镜和激光扫描共聚焦显微镜技术观察GFP或DsRed,荧光强度的变化。结果ALLN处理能使GFP“和DsRed2^u细胞内GFP和DsRed。含量明显增加,荧光强度显著增强,并呈现明显的剂量／时间-效应关系。结论本文成功地建立了检测内泛素-蛋白酶体系统活性的方法,该方法能有效地对活细胞的内泛素-蛋白酶体系统活性进行实时动态检测。     

PNRC1核定位信号序列的鉴定

为鉴定富含脯氨酸核受体辅调节蛋白1(PNRC1)分子的核定位信号序列（nuclear localization signal sequence, NLS）,在生物信息学方法预测的基础上,先构建野生型PNRC1及删除预测NLS的PNRC1突变体的绿色荧光蛋白（GFP）重组表达载体,转染细胞后通过激光共聚焦显微镜观察PNRC1分子在删除预测NLS后细胞内的定位变化.然后,将预测的NLS编码序列直接连到GFP表达载体上,以及将预测的NLS加到胞浆蛋白上构建其GFP重组表达载体,转染细胞,观察预测的NLS能否把构建的重组体都带到细胞核内.结果显示,删除PNRC1中预测的NLS后,其定位从细胞核中变为主要定位在细胞浆中,而预测的NLS能把GFP或胞浆中的蛋白带到细胞核中.研究表明,预测的NLS为PNRC1分子真正的NLS.     

绿色荧光蛋白在草鱼肾细胞中的表达

应用阳离子脂质体介导法,将含绿色荧光蛋白（GFP）基因的质粒pEGFP-N1转染到培养成单层的草鱼肾细胞（CIK）中,通过荧光倒置显微镜和特异性RT-PCR方法检测GFP的表达.在荧光倒置显微镜下可见CIK细胞的胞质和胞核均呈现绿色荧光,且细胞核的绿色荧光强度强于细胞质.转染细胞中的转录产物经RT-PCR扩增后,凝胶电泳鉴定出与GFP基因片段分子量大小一致的条带,经测序证明其为GFP基因序列.结果表明,GFP基因可以在草鱼CIK细胞内高效率成功表达,为构建以GFP为报告基因的真核重组质粒及研究草鱼出血病DNA疫苗奠定了重要的基础.     

用绿色荧光蛋白（GFP）作为报告分子筛选有效的siRNA

 建立一种利用绿色荧光蛋白（GFP）作为报告分子筛选能有效抑制目的基因表达的siRNA的方法.以巨噬细胞移动抑制因子（MIF）基因为研究对象,筛选能有效沉默MIF表达的质粒载体介导的siRNA.构建拥有同一Kozak共有翻译启始序列、翻译启始密码子ATG的MIF-GFP融合表达载体pEGFP-MIF.分别将3个靶向MIF的siRNA表达质粒与pEGFP-MIF共转化HEK293细胞,在荧光显微镜下观察HEK293细胞中GFP的表达,并用荧光定量PCR检测HEK293细胞中MIF mRNA的表达水平.同时,将MIF siRNA表达质粒分别与MIF表达载体共转化HEK293细胞,用荧光定量PCR检测HEK293细胞中MIF mRNA的表达水平.定量PCR结果显示,GFP表达低的细胞中,MIF mRNA的表达也明显降低;利用pEGFP-MIF和MIF表达载体筛选到的有效MIF siRNA的结果一致.因此,建立了目的基因与GFP融合表达,以GFP作为报告分子来筛选抑制目的基因表达siRNA的方法,并为进行多个基因的有效siRNA的筛选提供解决方案.     

人CUIAA重组腺病毒载体的构建及其在PC-12细胞中的表达特点

目的构建并鉴定带有绿色荧光蛋白（green fluorescence protein,GFP）报告基因的人源CUL4A（hCUIAA）基因腺病毒表达载体Ad—hCUIAA—GFP,探求bCUIAA在PC-12细胞中的表达特点。方法扩增hCUIAA基因,并通过In—FusionPCR克隆技术构建穿梭质粒pDC315-EGFP—hCUIAA,利用AdMaxTM腺病毒包装系统将该穿梭质粒与腺病毒表达载体骨架质粒pBHGloxAEl,E3Cre共转染HEK293细胞,经GFP荧光检测和Western印迹检测确认hCUIAA的表达后,进一步通过病毒扩增及纯化得到hCUL4A重组腺病毒载体Ad—hCUIAA—GFP。将该载体转染Pc—12细胞,观察hCUIAA—GFP融合蛋白在Pc-12细胞中的表达情况。结果成功获得了较高滴度的腺病毒载体Ad—hCUIAA—GFP（1．6×10^12pfu／m1）。荧光检测表明,Ad—hCUIAA—GFP转染Pc-12细胞后72h内,病毒转染率随着时间和病毒转染滴度的增加而增加。DAPI细胞核荧光染色结果表明,hCUIAA—GFP的表达主要集中在细胞质部分。GFP荧光检测及Western印迹检测结果显示,hCUIAA—GFP在Pc-12细胞中的表达量随时间和病毒转染滴度的增加而增加。结论带GFP的hCUIAA重组腺病毒载体Ad—hCUIAA—GFP构建成功,掌握了其转染Pc-12细胞的最佳滴度及其在Pc-12细胞中的时空表达特点,为今后对hCUIAA在PC-12细胞中的功能性研究奠定了基础。     

n-6脂肪酸去饱和酶fat-1基因对神经元细胞凋亡的抑制作用

将C．elegans n-6脂肪酸去饱和酶基因fat-1的cDNA插入到腺病毒的穿梭载体pAd-CMV中,并与骨架载体同源重组,构建腺病毒重组体（Ad．GFP．fat1）,通过包装细胞系（293）产生重组腺病毒,感染原代培养的大鼠皮层细胞．在显微镜下观察、细胞增殖试剂盒（MTT）和凋亡染色试剂盒分析fat-1基因对大鼠皮层细胞凋亡的影响,核糖核酸酶保护性分析,检测fat-1基因在大鼠皮层细胞内的表达,酶联免疫分析花生四烯酸类（Eicosanoids）前列腺素（Prostaglandin E2）的含量．结果表明,通过基因重组技术,得到预期的重组病毒;fat-1基因在原代培养的大鼠皮层细胞中能有效异源表达,2d后,可检测到fat-1 mRNA的条带,与对照Ad．GFP细胞相比,fat-1基因明显抑制了大鼠皮层细胞因诱导产生的凋亡（35％）,受保护细胞的前列腺素含量也明显地减少（30％）．     

人SDCT2β 3′-非翻译区基因表达负调控序列对mRNA稳定性的影响

为探索人高亲和力钠离子依赖性二羧酸转运蛋白基因（high affinity sodium-dependent dicarboxylate transporter,SDCT2）3′端非翻译区是否在基因表达调控中起作用,首先通过生物信息学分析发现,在SDCT2βmRNA的3′端非翻译区内存在585nt的AU富含区（AU-rich region,AUR）,其中包括3个AU富含元件（AU-rich element,ARE）,然后将SDCT2β的AU富含区DNA片段插入报告基因GFP表达载体pcDNA-GFP的下游,构建pcDNA-GFP-AUR表达载体并转染HEK293、HKC和LLC-PK1细胞系,用Western blot和流式细胞仪检测细胞中GFP的表达水平.结果显示,SDCT2β的AU富含区序列可显著降低GFP的表达水平（P〈0.01）.利用放线菌素D阻断RNA转录后,每隔2h从稳定转染的HEK293细胞中提取总RNA,用RNA印迹分析GFP mRNA的稳定性.结果显示GFP-AURmRNA较GFP mRNA不稳定.这些结果提示,在SDCT2β3′非翻译区的AU富含区内存在基因表达负调控区,该区可降低mRNA的稳定性、促进mRNA的降解,从而在转录后水平调控基因的表达.     

利用流式细胞仪分选拟南芥根尖发育早期非根毛细胞

建立了应用流式细胞仪分选植物特定类型细胞的方法。以拟南芥（Arabidopsis thaliana）Wer：：GFP转基因株系为材料,用激光共聚焦显微镜鉴定GFP的表达位置,采用酶解法制备拟南芥根尖原生质体,应用流式细胞仪荧光激活细胞分选技术（FACS）分选收集GFP阳性细胞,并提取细胞的RNA。结果表明,Wer：：GFP转基因株系仅在根表皮发育早期的非根毛细胞中表达GFP;利用酶解法制备的根尖原生质体数目较多;从FACS分选收集的细胞中提取的RNA质量较好,可用于研究特定类型细胞的基因表达谱。应用流式细胞仪分选拟南芥非根毛细胞的方法为研究植物特定类型细胞的基因表达谱及基因功能奠定了技术基础。     

绿色荧光蛋白表达载体pXS75－GFP的构建及在嗜热四膜虫中的应用

为获得能够用于构建嗜热四膜虫蛋白定位的载体,该研究将GFP基因与镉（Cd2＋）诱导的四膜虫金属硫蛋白基因（MTTl）启动子序列和终止子序列融合,获得表达载体pXS75-GFP。通过同源重组和抗性筛选,pXS75-GFP载体携带的目的基因整合入四膜虫MTTl位点,在cd2＋诱导下实现GFP融合蛋白的可控表达。将α－tubulin基因ATUl克隆JN－pXS75－GFP中,重组质粒pXS75－GFP－ATUl通过基因枪转化入四膜虫细胞,在巴龙霉素筛选下获得稳定的α-tubulin－GFP过表达细胞株。激光共聚焦显微镜观察α－tubulin．GFP的定位,结果显示,α－tubulin—GFP融合蛋白在四膜虫细胞中表达并分布于皮层上,表明pXS75．GFP载体可用于嗜热四膜虫功能蛋白的定位分析。     

表达绿色荧光蛋白的重组CVI988病毒的构建及特性

提取马立克氏病毒Ⅰ型疫苗毒株CVI988的总DNA为模板,利用PCR技术扩增出病毒生长非必需的US2基因并克隆入T—easy载体。将CMV启动子和增强子控制的含GFP基因表达盒克隆入US2基因中,成功构建了含GFP基因的转移质粒载体pGUS2GFP。用脂质体将其与CVI988株共转染CEF细胞,用96孔板稀释法得到纯化的表达绿色荧光蛋白的重组CVI988病毒株rCVIGFP,并分别测定其在体内和体外的生长情况。表达EGFP基因的重组病毒在细胞上生长曲线与亲本毒CVI988类似,体外实验表明,1日龄腹腔接种该重组毒后,可以从鸡体内分离到表达绿色荧光的病毒。     

绿色荧光蛋白基因在昆虫细胞中的克隆与表达

将绿色荧光蛋白(GFP)基因亚克隆到转移载体pVLneo的多角体蛋白基因(ocu)启动子下游,与杆状病素AcNPV DNA共转染昆虫细胞,通过同源重组和G418筛选,构建了整合有GFP基因的重组病毒。在昆虫细胞中表达的GFP,MW为30kDa,在荧光显微镜下呈现美丽的绿色,荧光光谱表明其激发波长395nm,发射波长509nm。Southern blot杂交证明,重组病毒的1kb EcoRI片段与GFP cDNA探针有很强的杂交信号,这是GFP基因在杆状病毒基因组中整合的直接证据。     

Efficient gene transfer into human CD34(+) cells by a retargeted adenovirus vector

Efficient infection with adenovirus (Ad) vectors based on serotype 5 (Ad5) requires the presence of coxsackievirus-adenovirus receptors (CAR) and alpha(v) integrins on cells. The paucity of these cellular receptors is thought to be a limiting factor for Ad gene transfer into hematopoietic stem cells. In a systematic approach, we screened different Ad serotypes for interaction with noncycling human CD34(+) cells and K562 cells on the level of virus attachment, internalization, and replication. From these studies, serotype 35 emerged as the variant with the highest tropism for CD34(+) cells. A chimeric vector (Ad5GFP/F35) was generated which contained the short-shafted Ad35 fiber incorporated into an Ad5 capsid. This substitution was sufficient to transplant all infection properties from Ad35 to the chimeric vector. The retargeted, chimeric vector attached to a receptor different from CAR and entered cells by an alpha(v) integrin-independent pathway. In transduction studies, Ad5GFP/F35 expressed green fluorescent protein (GFP) in 54% of CD34(+) cells. In comparison, the standard Ad5GFP vector conferred GFP expression to only 25% of CD34(+) cells. Importantly, Ad5GFP transduction, but not Ad5GFP/F35, was restricted to a specific subset of CD34(+) cells expressing alpha(v) integrins. The actual transduction efficiency was even higher than 50% because Ad5GFP/F35 viral genomes were found in GFP-negative CD34(+) cell fractions, indicating that the cytomegalovirus promoter used for transgene expression was not active in all transduced cells. The chimeric vector allowed for gene transfer into a broader spectrum of CD34(+) cells, including subsets with potential stem cell capacity. Fifty-five percent of CD34(+) c-Kit(+) cells expressed GFP after infection with Ad5GFP/F35, whereas only 13% of CD34(+) c-Kit(+) cells were GFP positive after infection with Ad5GFP. These findings represent the basis for studies aimed toward stable gene transfer into hematopoietic stem cells.     

鹅源新城疫病毒NP、P和L基因的克隆与P基因的表达鉴定

将鹅源新城疫病毒的NP、P和L基因通过RT-PCR方法从尿囊液中扩增后分别克隆进pGEM—T easy载体,再分别亚克隆到真核表达载体pCI—neo上,通过酶切、PCR和测序验证克隆正确。利用P基因开放性阅读框(ORF)上靠近终止密码上游的AgeI位点,将报告基因绿色荧光蛋白(GFP)基因克隆进P基因真核表达重组质粒,分别转染COS-1细胞和CEF细胞,在倒置荧光显微镜下可见到绿色荧光,表明GFP基因已得到表达,由此证明P基因也已得到表达。鹅源新城疫病毒NP、P和L基因的克隆成功,为即将进行的鹅源新城疫病毒的反向遗传操作以及功能基因组研究打下基础。     

Gene silencing in Xenopus laevis by DNA vector-based RNA interference and transgenesis

A vector-based RNAi expression system was developed using the Xenopus tropicalis U6 promoter, which transcribes small RNA genes by RNA polymerase Ⅲ. The system was first validated in a Xenopus laevis cell line, designing a short hairpin DNA specific for the GFP gene. Co-transfection of the vector-based RNAi and the GFP gene into Xenopus XR1 cells significantly decreased the number of GFP-expressing cells and overall GFP fluorescence. Vector-based RNAi was subsequently validated in GFP transgenic Xenopus embryos. Sperm nuclei from GFP transgenic males and RNAi construct-incubated-sperm nuclei were used for fertilization, respectively. GFP mRNA and protein were reduced by -60% by RNAi in these transgenic embryos compared with the control. This transgene-driven RNAi is specific and stable in inhibiting GFP expression in the Xenopus laevis transgenic line. Gene silencing by vector-based RNAi and Xenopus transgenesis may provide an alternative for ＇repression of gene function＇ studies in vertebrate model systems.     

Cnidarian and bilaterian promoters can direct GFP expression in transfected hydra

Complete sexual development is not easily amenable to experimentation in hydra. Therefore, the analysis of gene function and gene regulation requires the introduction of exogenous DNA in a large number of cells of the hydra polyps and the significant expression of reporter constructs in these cells. We present here the procedure whereby we coupled DNA injection into the gastric cavity to electroporation of the whole animal in order to efficiently transfect hydra polyps. We could detect GFP fluorescence in both endodermal and ectodermal cell layers of live animals and in epithelial as well as interstitial cell types of dissociated hydra. In addition, we could confirm GFP protein expression by showing colocalisation between GFP fluorescence and anti-GFP immunofluorescence. Finally, when a FLAG epitope was inserted in-frame with the GFP coding sequence, GFP fluorescence also colocalised with anti-FLAG immunofluorescence. This GFP expression in hydra cells was directed by various promoters, either homologous, like the hydra homeobox cnox-2 gene promoter, or heterologous, like the two nematode ribosomal protein S5 and L28 gene promoters, and the chicken beta-actin gene promoter. This strategy provides new tools for dissecting developmental molecular mechanisms in hydra; more specifically, the genetic regulations that take place in endodermal cells at the time budding or regeneration is initiated.     

Green fluorescent protein as a quantitative reporter of relative promoter activity in E. coli

Green fluorescent protein (GFP) has become a valuable tool for the detection of gene expression in prokaryotes and eukaryotes. To evaluate its potential for quantitation of relative promoter activity in E. coli, we have compared GFP with the commonly used reporter gene lacZ, encoding beta-galactosidase. We cloned a series of previously characterized synthetic E. coli promoters into GFP and beta-galactosidase reporter vectors. Qualitative and quantitative assessments of these constructs show that (a) both reporters display similar sensitivities in cells grown on solid or liquid media and (b) GFP is especially well suited for quantitation of promoter activity in cells grown on agar. Thus, GFP provides a simple, rapid and sensitive tool for measuring relative promoter activity in intact E. coli cells.